Design, Synthesis, and Biological Evaluation of Novel Imidazo[1,2-a

Mar 2, 2015 - A series of imidazo[1,2-a]pyridine derivatives against c-Met was designed by means of bioisosteric replacement. In this study, a selecti...
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Design, Synthesis and Biological Evaluation of Novel Imidazo[1,2-a]pyridine Derivatives as Potent c-Met Inhibitors Chunpu Li, Jing Ai, Dengyou Zhang, Xia Peng, Xi Chen, Zhiwei Gao, Yi Su, Wei Zhu, Yinchun Ji, Xiaoyan Chen, Mei-Yu Geng, and Hong Liu ACS Med. Chem. Lett., Just Accepted Manuscript • Publication Date (Web): 02 Mar 2015 Downloaded from http://pubs.acs.org on March 4, 2015

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ACS Medicinal Chemistry Letters

Design, Synthesis and Biological Evaluation of Novel Imidazo[1,2-a]pyridine Derivatives as Potent c-Met Inhibitors Chunpu Li,†,ǁ Jing Ai,‡,ǁ Dengyou Zhang,†,ǁ Xia Peng,‡ Xi Chen,† Zhiwei Gao,§ Yi Su, ‡ Wei Zhu,† Yinchun Ji,‡ Xiaoyan Chen,§ Meiyu Geng*,‡ and Hong Liu*,† †

CAS Key Laboratory of Receptor Research, ‡Division of Anti-Tumor Pharmacology, Shanghai Institute of Materia Medica, Chinese Academy of Sciences, 555 Zu Chong Zhi Road, Shanghai 201203, P. R. China §

Shanghai Institute of Materia Medica, Chinese Academy of Sciences, 501 Haike Road, Shanghai 201203, P. R. China

KEYWORDS: Receptor tyrosine kinase, c-Met inhibitor, imidazo[1,2-a]pyridine, metabolic stability

ABSTRACT: A series of imidazo[1,2-a]pyridine derivatives against c-Met was designed by means of bioisosteric replacement. In this study, a selective, potent c-Met inhibitor, 22e was identified, with IC50 values of 3.9 nM against c-Met kinase and 45.0 nM against c-Met-addicted EBC-1 cell proliferation, respectively. 22e inhibited c-Met phosphorylation and downstream signaling across different oncogenic forms in c-Met over-activated cancer cells and model cells. 22e significantly inhibited tumor growth (TGI = 75%) with good oral bioavailability (F = 29%) and no significant hERG inhibition. Based on systematic metabolic study, the pathway of all possible metabolites of 22e in liver microsomes of different species has been proposed, and a major NADPH-dependent metabolite 33 was generated by liver microsomes. To block the metabolic site, 42 was designed and synthesized for further evaluation. Taken together, the imidazo[1,2-a]pyridine scaffold showed promising pharmacological inhibition of c-Met and warrants further investigation.

Receptor tyrosine kinases (RTKs) have a critical role in the development and progression of many types of cancer.1 The receptor tyrosine kinase c-Met is expressed mainly by epithelial cells of many organs.2 Activation of c-Met is regulated upon binding with its natural ligand, hepatocyte growth factor (HGF),3 and interaction with other membrane receptors.4 The normal functions of HGF/c-Met pathway are largely restricted to embryogenesis, tissue injury repair and regeneration in adults.5 Dysregulation of the HGF/c-Met pathway (through, e.g., c-Met transcriptional upregulation, MET gene amplification or rearrangement, and activating mutations of MET gene) can induce cell proliferation, invasion, migration, and apoptosis avoidance, leading to tumor growth, angiogenesis and metastasis.3 Importantly, aberrant c-Met activation observed frequently in many human solid tumors and hematological malignancies is associated with poor clinical outcomes.6 Furthermore, overactivation of c-Met causes therapeutic resistance.7 For these reasons, c-Met has become an attractive target for cancer therapy. Recently, a numerous number of small molecule c-Met inhibitors have been reported (Figure 1). Compound 1 (Crizotinib)8 developed by Pfizer is a potent c-Met/ALK dual inhibitor that demonstrated marked efficacy for a subset of non-small cell lung cancer (NSCLC) patients with an EML4-ALK fusion gene. Phase I clinical trial of inhibitor 2 (JNJ38877605)9 has been terminated because of an increase in serum creatinine levels. Inhibitor 3

(SGX-523) is no longer in clinical development, because of acute renal failure.10 Without any safety concerns, the clinical study of inhibitor 4 (PF-04217903)11 was prematurely discontinued. In addition, compounds 5 (AMG337)12 and 6 (INC-280)13 were reported and have entered phase II clinical trials. Figure 1 Among the known c-Met inhibitors, bicyclic triazolebased or triazine-based inhibitors demonstrated high cMet inhibitory potency and excellent selectivity against other kinases. However, many projects of these inhibitors in clinical or discovery development were stopped due to toxicity or unknown reasons.9,10,14 Thus, there is still a need to discover new classes of inhibitors against c-Met for the treatment of cancer patients. The publicly available cocrystal structure of PF-04217903 within c-Met (PDB 3ZXZ) disclosed the binding mode of this kind of inhibitors.11 Generally, the quinoline nitrogen atom participates in a hydrogen bond with the hinge region residue Met1160. The N-3 nitrogen of triazolopyrazine backbone formed a hydrogen bond with Asp-1222. Meanwhile, triazolopyrazine backbone play an important role in both cMet activity and kinase selectivity via the unique face-toface π-stacking interaction with the activation loop residue Tyr-1230, and there is a positive correlation between electron deficiency of bicyclic aromatic rings and the strength of π−π interaction with Tyr-1230.11 The substituted aryl/heteroaryl (e.g., 1-Methylpyrazole) on the back-

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bone reaches out into the solvent (Figure 2). Bioisosteric replacement is a powerful method for the identification of novel chemical series in medicinal chemistry. Based on the previous work by Merck, 8-fluoroimidazo[1,2a]pyridine has been established as a physicochemical mimic of imidazo[1,2-a]pyrimidine, using both in silico and traditional techniques.15 To the best of our knowledge, there are still no examples of using this strategy to discover novel c-Met inhibitors. Hence, we tried to replace the 8-position N atom with a C-F bond to mimic the properties of N-8 atom, including electrostatic surface and lipophilicity to keep the electron deficiency of bicyclic aromatic rings. Meanwhile, we tried to introduce Cl, CN and CF3 on the imidazo[1,2-a]pyridine to evaluated the effluence of the electron density of bicyclic aromatic rings on c-Met inhibition. On the basis of the cocrystal structural information and principles of bioisosterism, we designed a novel imidazo[1,2-a]pyridine scaffold as c-Met inhibitors. Herein, we describe our recent effort on the synthesis and SARs of this series of compounds. Figure 2 To achieve a structure−activity relationship (SAR) exploration, efficient synthetic routes were employed for preparation of the analogues (Scheme 1 and 2 in Supporting Information). These novel imidazo[1,2-a]pyridine derivatives against c-Met have not been previously synthesized and evaluated; therefore, the initial goal was to identify the optimal substituent. To identify potent c-Met inhibitors efficiently, we initially selected 1-methylpyrazole as a substituent at the C-6 position while varying the C-7 and C-8 substituents (Table 1). The initial biochemical assay found that compound 15a exhibited moderate activity with an enzymatic IC50 of 2.18 μM against c-Met. The activity did not significantly change with the introduction of different substituents at the C-7 or C-8 position (15b-15f). To our delight, compound 15g exhibited c-Met inhibition with an enzymatic IC50 of 7.8 nM and an EBC-1 cell IC50 of 0.27 μM, respectively. These encouraging results prompted us to investigate the SAR for substituents on the pyrazole while keeping the fluorine substitute at the C-8 position. The incorporation of polar groups, such as an ethanolic group (15h) and a piperidine group (15i) on the pyrazole of 15g resulted in 1.2-fold and 5.4-fold loss of cellular potency, respectively. Table 1 To gain structural information for further optimization, the 3D proposed binding modes of representative compounds 15a, 15c, 15e and 15g were generated by docking simulation (Figure 3). For each compound, the best pose with the lowest binding energy was selected for further analysis with Glide16 and PyMOL17. The binding mode indicated that compound 15g was bound to the active site of c-Met in a similar to PF-04217903 (Figure 3A). The nitrogen of quinoline H-bonds well with the hinge region Met-1160, whereas the N-1 nitrogen of the imidazo[1,2a]pyridine scaffold formed a hydrogen bond with Asp1222. In addition, imidazo[1,2-a]pyridine core kept a π−π

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interaction with electron rich Tyr-1230, which is critical for c-Met inhibition. Compared with 15g, the binding pose of 15c (Figure 3B) was entirely different since the bulky C-8 CF3 substituent could not enter the inside pocket, which could be the main reason for the loss in inhibitory activity. Compared to 8-fluoroimidazo[1,2a]pyridine core (15g), the 8-chloroimidazo[1,2-a]pyridine is more electron rich, leading to a decreased interaction with Tyr-1230. Taken together, these results could give an explanation to the different inhibition of these compounds. Figure 3 Subsequently, the structure activity relationship at the 6-position of the imidazo[1,2-a]pyridine scaffold was investigated (Table 2). Introduction of heteroaryl substituents (16a-c) displayed good c-Met inhibition. The pyridinyl analog 16b, which incorporated a cyano group, was more effective and the EBC-1 cell IC50 reached to 188.5 nM. Among the phenyl derivatives (16d-g), benzonitrile analogs 16d and 16f demonstrated improved c-Met inhibition, with an EBC-1 cell IC50 of 106.7 and 145.0 nM, respectively. These observations indicated that incorporation of polar groups on 6-phenyl had a significant influence on cellular activity. Encouraged by these results, analogs incorporated polar amide groups on 6-phenyl were prepared for SAR exploration. 6-Benzamide analog 22a displayed 4-fold loss in cellular activity compared to 16d. Derivatives bearing 4-fluoro-3-N-methylbenzamide (22b) and 4-chloro-3-N-methylbenzamide (22c) groups displayed less potent c-Met inhibition than 22a. However, derivatives bearing 3-methoxy-4-N-methylbenzamide (22d) and 3-fluoro-4-N-methylbenzamide (22e) groups exhibited remarkably improved cellular activity. In particular, compound 22e showed an enzymatic IC50 of 3.9 nM and good EBC-1 cell IC50 of 45.0 nM. These results indicated that the 3-F and 3-OMe might be important for c-Met inhibition. Table 2 To further modulate physical chemical properties of these inhibitors, substituted amides were introduced, especially amides with polar groups such as basic amines on their N-terminus (Table 3). Firstly, the N,N’disubstituted amide analogs were evaluated. Compounds 22f and 22g showed an EBC-1 cell IC50 of 405.5 and 868.9 nM respectively, suggesting that N-monosubstituents were preferred here. Next, we investigated the influence of mono-substitution of the N-terminus of the amide on c-Met inhibition. For example, compound 22h, which contained a morpholinoethyl group on the N-terminus of the amide, demonstrated c-Met inhibition by 2-fold compared with 22e, and there was no significant differences between their EBC-1 activity. Replacement of the morpholinoethyl group with a non-cyclic dimethylaminoethyl group (compound 22i, enzymatic IC50= 2.4 nM and EBC-1 cell IC50 = 49 nM) slightly improved the cell inhibitory activity. Compound 22j, with a longer C-chain of the amide, reduced EBC-1 cell inhibitory activity by 3-fold. We also investigated the SARs of the compounds by restrict-

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ing the side-chain conformation at the N-terminus of the amides (compounds 22k, 22l and 22o). When the Nterminus of the amide was replaced with a piperidin-2ylmethyl group (compound 22k, EBC cell IC50 = 276.8 nM) or a piperidin-3-yl group (compound 22l, EBC cell IC50 = 137.5 nM), c-Met inhibition was 5.5- and 4.3-fold more potent than 22e, respectively. In addition, we investigated compounds that contained an aryl group or a heteroaryl group on the N-terminal side of the amides. Compound 22m showed sharply decreased c-Met cell inhibition, which could be caused by an intramolecular hydrogen bond interaction between the hydrogen atom of the amide and the pyridine nitrogen. The potency of compound 22n against EBC-1 cell proliferation is comparable to that of optimal compound 22e. Table 3 Given its promising enzymatic and cellular potency, 22e was selected as the lead compound for subsequent evaluation. In contrast to its high potency against c-Met, 22e had barely any inhibitory effect on the other 21 tested kinases, including c-Met family member RON and highly homologous kinases Axl, c-Mer, Tyro-3 (IC50>10 μM), indicating that 22e was a selective c-Met inhibitor (Table S1 in Supporting Information). As shown in Figure S1 (See Supporting Information), 22e inhibited the phosphorylation of c-Met and its key downstream molecules Akt and Erk in a dose-dependent manner in representative cancer or model cell lines (EBC1, MKN45, BaF3/TPR-Met cells). These results suggested that 22e suppressed c-Met signaling across different oncogenic forms in c-Met over-activated cells. 22e significantly inhibited cell proliferation of EBC-1, MKN-45, SNU-5, and BaF3/TPR-Met cells, which are characterized by a c-Met-dependent cell growth, with an IC50 value of 45.0 to 203.2 nM (Table 4), however, 22e barely inhibited these other cell lines, of which had Met low expression or activation (IC50>50 μM) (Figure S2A in Supporting Information). c-Met inhibition blocks cell proliferation via arresting cells in G1/S phase.18 22e induced a G1/S phase arrest in the EBC-1 cells, with 81.84% of the cell population in G1 phase in the presence of 1 μM 22e (versus 52.95% in the vehicle control group) (Figures S2B-C in Supporting Information).

(Figures S4 in Supporting Information). Collectively, these results indicated that 22e inhibited the metastasis and invasiveness phenotype evoked by the HGF/c-Met axis in cancer. Upon HGF stimulation, c-Met induces several biological responses that collectively give rise to a program known as invasive growth, which is pivotal to drive cancer cell invasion and metastasis.22 Thus, we investigated whether 22e inhibited c-Met-mediated invasive growth. Exposure to 22e inhibited branching morphogenesis in MDCK cells (Figures S5 in Supporting Information), indicating the 22e inhibited HGF-induced c-MET-mediated invasive growth. The pharmacokinetic (PK) profiles of the selected compound 22e were assessed in Sprague-Dawley (SD) rats (Table S2 in Supporting Information). Compound 22e showed a high area under the curve (AUC0-∞) when dosed orally. The half-life and the absolute oral bioavailability of compound 22e were 1.17 h and 29.4%, respectively. We used the ultra-performance liquid chromatography quadrupole time of flight mass spectrometry (UPLCqTOF-MS) method to identify the possible metabolites of 22e in liver microsomes of different species. We have proposed the metabolism pathway and all the metabolites of 22e (Scheme 3a in Supporting Information). In view of the result that the major oxidant metabolism take place in the benzyl position of this scaffold, we speculated that metabolite 33 was the major metabolite of 22e after incubation in mice, dog, monkey, and human liver microsomes, except rat liver microsomes (Table S3 in Supporting Information). The IC50 value of compound 22e on hERG was 93.56 μM using a FluxORTM thallium assay. Thus, 22e did not show significant hERG inhibition. To assess the in vivo antitumor efficacy of 22e, an EBC-1 xenograft model specifically driven by MET amplification was chosen. After 21-days of 22e (methanesulfonic salt) oral administration, dose-dependent tumour growth inhibition was observed in 22e treated groups, with an inhibitory rate of 75.0% (P